SUMO-2 and PIAS1 Modulate Insoluble Mutant Huntingtin Protein Accumulation

SUMMARY A key feature in Huntington disease (HD) is the accumulation of mutant Huntingtin (HTT) protein, which may be regulated by posttranslational modifications. Here, we define the primary sites of SUMO modification in the amino-terminal domain of HTT, show modification downstream of this domain, and demonstrate that HTT is modified by the stress-inducible SUMO-2. A systematic study of E3 SUMO ligases demonstrates that PIAS1 is an E3 SUMO ligase for both HTT SUMO-1 and SUMO-2 modification and that reduction of dPIAS in a mutant HTT Drosophila model is protective. SUMO-2 modification regulates accumulation of insoluble HTT in HeLa cells in a manner that mimics proteasome inhibition and can be modulated by overexpression and acute knockdown of PIAS1. Finally, the accumulation of SUMO-2-modified proteins in the insoluble fraction of HD postmortem striata implicates SUMO-2 modification in the age-related pathogenic accumulation of mutant HTT and other cellular proteins that occurs during HD progression

Minimizing variables among hairpin-based RNAi vectors reveals the potency of shRNAs

RNA interference (RNAi) is a cellular process regulating gene expression and participating in innate defense in many organisms. RNAi has also been utilized as a tool to query gene function and is being developed as a therapeutic strategy for several diseases. Synthetic small interfering (siRNAs) or expressed stem–loop RNAs (short-hairpin RNAs [shRNAs] or artificial microRNAs [miRNAs]) have been delivered to cultured cells and organisms to inhibit expression of a variety of genes. A persistent question in the field, however, is which RNAi expression system is most suitable for distinct applications. To date, shRNA- and artificial miRNA-based strategies have been compared with conflicting results. In prior comparisons, sequences required for efficient RNAi processing and loading of the intended antisense strand into the RNAi-induced silencing complex (RISC) were not considered. We therefore revisited the shRNA–miRNA comparison question. Initially, we developed an improved artificial miRNA vector and confirmed the optimal shRNA configuration by altering structural features of these RNAi substrates. Subsequently, we engineered and compared shRNA- and miRNA-based RNAi expression vectors that would be processed to yield similar siRNAs that exhibit comparable strand biasing. Our results demonstrate that when comparison variables are minimized, the shRNAs tested were more potent than the artificial miRNAs in mediating gene silencing independent of target sequence and experimental setting (in vitro and in vivo). In addition, we show that shRNAs are expressed at considerably higher levels relative to artificial miRNAs, thus providing mechanistic insight to explain their increased potency

Artificial miRNAs Targeting Mutant Huntingtin Show Preferential Silencing In Vitro and In Vivo

Huntington's disease (HD) is a dominantly inherited neurodegenerative disease caused by CAG repeat expansion in exon 1 of huntingtin (HTT). Studies in mouse models of HD with a regulated mutant transgene show that continuous mutant allele expression is required for behavioral and pathological signs; when mutant HTT expression declined, neuronal degeneration improved. To date, it is unknown whether neural cells in the adult human brain can tolerate reduction in both normal and mutant alleles. Thus, it may be important to develop allele-specific silencing approaches. Several siRNA sequences targeting the CAG expanded motif or prevalent single-nucleotide polymorphisms (SNPs) in linkage disequilibrium with the mutant allele have been designed and their selectivity demonstrated in vitro. However, it is unknown whether these allele-specific siRNAs will retain their specificity when expressed from artificial RNAi platforms. Here, we designed CAG- and SNP- targeting artificial miRNAs and demonstrate that some, but not all, retained their selectivity in vitro using an allele-specific reporter system and in vivo in a transgenic mouse model developed to express normal and mutant human HTT alleles

PIAS1 Regulates Mutant Huntingtin Accumulation and Huntington’s Disease-Associated Phenotypes In Vivo

The disruption of protein quality control networks is central to pathology in Huntington's disease (HD) and other neurodegenerative disorders. The aberrant accumulation of insoluble high-molecular-weight protein complexes containing the Huntingtin (HTT) protein and SUMOylated protein corresponds to disease manifestation. We previously identified an HTT-selective E3 SUMO ligase, PIAS1, that regulates HTT accumulation and SUMO modification in cells. Here we investigated whether PIAS1 modulation in neurons alters HD-associated phenotypes in vivo. Instrastriatal injection of a PIAS1-directed miRNA significantly improved behavioral phenotypes in rapidly progressing mutant HTT (mHTT) fragment R6/2 mice. PIAS1 reduction prevented the accumulation of mHTT and SUMO- and ubiquitin-modified proteins, increased synaptophysin levels, and normalized key inflammatory markers. In contrast, PIAS1 overexpression exacerbated mHTT-associated phenotypes and aberrant protein accumulation. These results confirm the association between aberrant accumulation of expanded polyglutamine-dependent insoluble protein species and pathogenesis, and they link phenotypic benefit to reduction of these species through PIAS1 modulation

Structure and activity of putative intronic miRNA promoters

MicroRNAs (miRNAs) are RNA sequences of ∼22 nucleotides that mediate post-transcriptional regulation of specific mRNAs. miRNA sequences are dispersed throughout the genome and are classified as intergenic (between genes) or intronic (embedded into a gene). Intergenic miRNAs are expressed by their own promoter, and until recently, it was supposed that intronic miRNAs are transcribed from their host gene. Here, we performed a genomic analysis of currently known intronic miRNA regions and observed that ∼35% of intronic miRNAs have upstream regulatory elements consistent with promoter function. Among all intronic miRNAs, 30% have associated Pol II regulatory elements, including transcription start sites, CpG islands, expression sequence tags, and conserved transcription factor binding sites, while 5% contain RNA Pol III regulatory elements (A/B box sequences). We cloned intronic regions encompassing miRNAs and their upstream Pol II (miR-107, miR-126, miR-208b, miR-548f-2, miR-569, and miR-590) or Pol III (miR-566 and miR-128-2) sequences into a promoterless plasmid, and confirmed that miRNA expression occurs independent of host gene transcription. For miR-128-2, a miRNA overexpressed in acute lymphoblastic leukemia, ChIP analysis suggests dual regulation by both intronic (Pol III) and host gene (Pol II) promoters. These data support complex regulation of intronic miRNA expression, and have relevance to disregulation in disease settings

Reinstating Aberrant mTORC1 Activity in Huntington’s Disease Mice Improves Disease Phenotypes

Huntington's disease (HD) is caused by a polyglutamine tract expansion in huntingtin (HTT). Despite HTTs ubiquitous expression, there is early and robust vulnerability in striatum, the cause of which is poorly understood. Here, we provide evidence that impaired striatal mTORC1 activity underlies varied metabolic and degenerative phenotypes in HD brain and show that introducing the constitutively active form of the mTORC1 regulator, Rheb, into HD mouse brain, alleviates mitochondrial dysfunction, aberrant cholesterol homeostasis, striatal atrophy, impaired dopamine signaling, and increases autophagy. We also find that the expression of Rhes, a striatum-enriched mTOR activator, is reduced in HD patient and mouse brain and that exogenous addition of Rhes alleviates motor deficits and improves brain pathology in HD mice. Our combined work indicates that impaired Rhes/mTORC1 activity in HD brain may underlie the notable striatal susceptibility and thus presents a promising therapeutic target for HD therapy

The Transcription Factor ATF4 Promotes Skeletal Myofiber Atrophy during Fasting

Prolonged fasting alters skeletal muscle gene expression in a manner that promotes myofiber atrophy, but the underlying mechanisms are not fully understood. Here, we examined the potential role of activating transcription factor 4 (ATF4), a transcription factor with an evolutionarily ancient role in the cellular response to starvation. In mouse skeletal muscle, fasting increases the level of ATF4 mRNA. To determine whether increased ATF4 expression was required for myofiber atrophy, we reduced ATF4 expression with an inhibitory RNA targeting ATF4 and found that it reduced myofiber atrophy during fasting. Likewise, reducing the fasting level of ATF4 mRNA with a phosphorylation-resistant form of eukaryotic initiation factor 2α decreased myofiber atrophy. To determine whether ATF4 was sufficient to reduce myofiber size, we overexpressed ATF4 and found that it reduced myofiber size in the absence of fasting. In contrast, a transcriptionally inactive ATF4 construct did not reduce myofiber size, suggesting a requirement for ATF4-mediated transcriptional regulation. To begin to determine the mechanism of ATF4-mediated myofiber atrophy, we compared the effects of fasting and ATF4 overexpression on global skeletal muscle mRNA expression. Interestingly, expression of ATF4 increased a small subset of five fasting-responsive mRNAs, including four of the 15 mRNAs most highly induced by fasting. These five mRNAs encode proteins previously implicated in growth suppression (p21Cip1/Waf1, GADD45α, and PW1/Peg3) or titin-based stress signaling [muscle LIM protein (MLP) and cardiac ankyrin repeat protein (CARP)]. Taken together, these data identify ATF4 as a novel mediator of skeletal myofiber atrophy during starvation